An electrical equipment includes a first load configured for a nominal use of the equipment, at least one first metal screen, a sensor configured to measure a quantity characteristic of the first load, and a power supply conductor, wherein the first load and the at least first metal screen are linked electrically to the power supply conductor, and in that the equipment also comprises a comparator configured to compare measurements from the sensor to detect a dormant failure of the at least first metal screen.
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1. An electrical equipment comprising:
a transformer;
a first load configured for a nominal use of the equipment;
a sensor configured to measure a quantity characteristic of the first load; and
a power supply conductor,
wherein the transformer comprises a primary winding, at least one secondary winding and at least one first metal screen placed between the primary winding and the at least one secondary winding, the first load and the at least first metal screen are linked electrically to the power supply conductor, and wherein the equipment also comprises a comparator configured to compare measurements from the sensor to detect a dormant failure of the at least first metal screen.
2. The electrical equipment according to
3. The electrical equipment according to
4. The electrical equipment according to
5. The electrical equipment according to
6. A method for detecting the dormant failure and ensuring the safety of equipment according to
a) defining a range of values of a quantity characteristic of the first load guaranteeing the good operation of the equipment;
b) measuring, with the sensor, the quantity characteristic of the first load;
c) comparing with the comparator the quantities measured in the step b) with the range of values defined in the step a); and
d) cutting the link to the electrical power supply system from the equipment if the quantity measured in the step b) is outside of the range defined in the step a).
7. The detection method according to
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This application claims priority to foreign French patent application No. FR 1871452, filed on Nov. 8, 2018, the disclosure of which is incorporated by reference in its entirety.
The invention relates to a method for detecting and transmitting information on dormant failure of electrical equipment in a critical environment in which a non-detection of a dormant failure, for example failure of the device making it possible to detect a break of insulation in a transformer, can present a risk for the people and the installations.
A transformer makes it possible to convert an alternative electrical energy source into magnetic energy and vice versa, the converted energy being of the same frequency as the energy from the initial source. It is composed of primary and secondary windings which have no electrical link between them, only a magnetic coupling. It is powered by one or more alternating voltages, called phases, each via a primary winding which constitutes an input of the transformer. One or more secondary windings make up the outputs of the transformer. A set of primary and secondary windings depending on one and the same input voltage is called coil. There are therefore as many coils as there are phases at the input of the transformer. The transformer makes it possible to exchange energy between the primary windings and the secondary windings without them having to exchange electrons by virtue of the magnetic coupling. The passage through a magnetic medium makes it possible to create a galvanic insulation between the electrical energy passing through the primary winding and the electrical energy passing through the secondary winding, and to raise or lower the amplitudes of the voltages or currents entering into the primary winding and leaving from the second winding through the transformation ratio of the transformer. It can also supply the same voltage or current level between the input and the output of the transformer and simply serve as galvanic insulation.
However, if this galvanic insulation disappears, referred to as a break of insulation, the electrons can circulate from the primary winding to the secondary winding and the transformation ratio of the transformer is no longer guaranteed. Thus, the voltage from the secondary winding can, in the case of a voltage step-down or current step-up transformer, rise above the voltage for which the equipment connected to it is designed and lead to the destruction thereof.
Furthermore, the break of insulation can be sudden and undetectable, and in the current transformers, used for example in aeronautics, it can instantaneously generate a “dreaded failure mode”, such as the increase of the voltage in the secondary windings. In order to limit the occurrence of fault of loss of insulation, it is possible to place metal screens, surrounded by thermal insulations, between the primary and secondary windings, the screens being linked to the electrical ground by dedicated wiring. The detection of the break of insulation is then done using, for example, the measurement of a ground leakage current. However, the low point of this solution lies in the grounding of the screens. If the screen/ground link is lost, then the detection is impossible, since this link is not used in the context of a nominal use. In the absence of a dedicated control, the link break between the screen and the ground forms an example of dormant failure.
In order to avoid the loss of link between the ground and the screen, or more generally between a load not used in nominal use and a power supply conductor, it is possible to reinforce the electrical link to avoid the degradation thereof in operation and take particular precautions in production not to inject defects that can lead to a subsequent break. Nevertheless, the loss of link remains undetectable and therefore still constitutes a dormant failure.
The invention aims to overcome the abovementioned drawbacks and limitations of the prior art. More specifically, it aims to propose a method for detecting and transmitting dormant failure information and electrical equipment capable of detecting a dormant failure, such as, for example, the loss of link between a metal screen and a power supply conductor.
One object of the invention is therefore electrical equipment comprising a first load configured for a nominal use of the equipment, at least one first metal screen, a sensor configured to measure a quantity characteristic of the first load, and a power supply conductor, characterized in that the first load and the at least first metal screen are linked electrically to the power supply conductor, and in that the equipment also comprises a comparator configured to compare measurements from the sensor to detect a dormant failure of the at least first metal screen.
According to particular embodiments of the invention:
Another subject of the invention is a method for detecting the dormant failure and ensuring the safety of equipment according to the invention linked to an electrical power supply system, characterized in that it comprises the following steps:
According to a particular embodiment of the invention, the quantity measured in the step b) is chosen from among a speed, an electrical current, a voltage or a temperature.
Other features, details and advantages of the invention will emerge from reading the description given with reference to the attached figures given by way of example and which represent, respectively:
According to one embodiment, the comparator COMP can compare the measured values of G with one another over time or compare the values of G with a reference REF. This reference REF can be, for example, a particular value of the quantity G or a range of values of G. The reference REF defines, for example, a value or a range guaranteeing the good operation of the equipment EE. This comparison makes it possible to detect a dormant failure of the equipment EE. For example, the dormant failure can be a failure at the level of the metal screen E, such as a loss of link between the screen E and the power supply conductor CALIM.
According to one embodiment, the electrical equipment EE is an electrical transformer comprising a metal screen E placed between a primary winding and a secondary winding of a coil of the electrical transformer.
According to embodiments of the invention, the comparator COMP is an electrical circuit comprising, for example, an operational amplifier, or the comparator COMP is a computer.
According to embodiments, the first load C1 is an element of the equipment EE, a signal or one of the characteristic quantities of which is permanently monitored in the nominal use of the equipment.
According to embodiments, the sensor CAP is a temperature, or electrical current or voltage or speed sensor.
It is possible to link the metal screens E together in series, as is illustrated in
The series-connection of the screens E makes it possible notably to be able to detect a loss of link between the power supply conductor, such as the electrical ground ME, and a screen E, but also to detect a loss of link between two screens E, if the connection between the screen E and the power supply conductor is chosen appropriately (
According to several embodiments of the invention, the first load C1 can be a fan, or an electronic circuit board or a contactor.
According to several embodiments, the measured quantity characteristic of the first load can be:
Indeed, whatever the nature of the first load, it is possible to measure the current passing through that load, the voltage at the terminals of that load, or the temperature of that load. In the case of a transformer comprising a metal screen between the different primary and secondary windings, the dormant failure can for example be the loss of link between the electrical ground and the screen. If the first load is a fan, in case of loss of link, the fan will stop turning, therefore the measurement of its speed of rotation will indeed make it possible to detect this dormant failure. If the first load is an electronic circuit board, in case of loss of link, the temperature of the board will increase and either this rise in temperature will be detected or the information concerning this temperature will not be received. Whether or not the temperature information is received, that will not be the reference value or the reference range REF, therefore the loss of link will be detected. If a current is measured, in case of loss of link, the current will drop and, as previously, either the current drop will be detected, or the information concerning the current values of the first load will not be received, therefore the loss of link will also be detected.
Biaujaud, Rémy, Mairie, Mathieu, Mariadassou, Prithu
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